CN111966066B - Equipment data processing method and device and electronic equipment - Google Patents

Abstract

The embodiment of the application provides a device data processing method, a device and electronic equipment, wherein the method comprises the following steps: responding to dynamic configuration operation of target equipment, and obtaining component level configuration information in the dynamic configuration operation based on preset data and the selected target equipment, wherein the preset data comprises an equipment type table, an attribute summary table and a component type table; and generating a relation data model based on the component-level configuration information, wherein the relation data model is used for reflecting the process parameters of each device in the device process and/or the component-level connection relation among the devices. Therefore, the problem that the equipment management scheme in the prior art cannot reflect the engineering attributes of each piece of equipment in the engineering application scene can be solved.

Description

Equipment data processing method and device and electronic equipment

Technical Field

The present application relates to the field of process engineering technologies, and in particular, to a device data processing method and apparatus, and an electronic device.

Background

With the development of the refining industry, the processes and equipment related to oil refining and chemical engineering become more and more complex, and the equipment used in the refining process can roughly comprise fluid conveying equipment, heating equipment, heat exchange equipment, mass transfer equipment, reaction equipment, storage equipment and the like. Among various devices, some devices are mainly used for oil refining and chemical production, such as heating furnaces, reaction devices, tower devices, heat exchange devices and the like, and some devices can be used for oil refining and chemical production and can also be applied to other aspects, such as various types of pumps, compressors, fans, valves and the like.

In order to perform equipment management, one equipment management technology in the prior art is mainly used for recording information such as equipment sources, equipment use time, maintenance records and the like so as to realize equipment management, but the method has the attention point in daily maintenance of the equipment and cannot reflect the engineering attributes of each equipment in an engineering application scene.

Disclosure of Invention

An object of the embodiments of the present application is to provide a device data processing method, an apparatus, and an electronic device, which can solve a problem that a device management scheme in the prior art cannot reflect engineering attributes of each device in an engineering application scenario.

In a first aspect, an embodiment of the present application provides an apparatus data processing method, where the method includes:

responding to dynamic configuration operation of target equipment, and obtaining component level configuration information in the dynamic configuration operation based on preset data and the selected target equipment, wherein the preset data comprises an equipment type table, an attribute summary table and a component type table;

and generating a relation data model based on the component-level configuration information, wherein the relation data model is used for reflecting the process parameters of each device in the device process and/or the component-level connection relation among the devices.

By the method, the equipment management can be implemented to the component level, the equipment component datamation and the equipment connection relation datamation are realized, the equipment process with rich engineering attributes is embodied through the relation data model generated based on the component level configuration information, and the equipment management is realized.

In an optional embodiment, the dynamic configuration operation includes a component configuration operation, and the obtaining, in response to the dynamic configuration operation on the target device, component-level configuration information in the dynamic configuration operation based on preset data and the selected target device includes: responding to the selected operation of the target equipment, acquiring the equipment identity of the target equipment, and determining the equipment type of the target equipment based on the equipment type table by taking the equipment identity of the target equipment as a key value; responding to the component configuration operation of the target equipment, determining at least one component from all components provided by the component type table as the target component of the target equipment based on the equipment type of the target equipment, and determining at least one process attribute item from the attribute summary table as an item to be configured of the target component according to the type of the target component; and taking the component name recorded aiming at the target component in the component configuration operation and the process attribute parameter recorded aiming at the item to be configured of the target component as the component-level configuration information of the target component. Therefore, proprietary component-level engineering attributes can be input into the target equipment, and a relational data model generated based on the obtained component-level configuration information can have component-level process attribute characteristics.

In an optional implementation manner, the determining, based on the device type of the target device, at least one component from all components provided by the component type table as a target component of the target device, and determining, according to the type of the target component, at least one process attribute item from the attribute summary table as an item to be configured of the target component includes: calling a preset first mapping relation between the equipment type table and the component type table based on the equipment type of the target equipment, and screening out at least one component which meets the first mapping relation from all components provided by the component type table to serve as a target component of the target equipment; and calling a second mapping relation between the preset component type table and the attribute summary table based on the component type of the target component, and screening out at least one process attribute item which accords with the second mapping relation from all attribute items provided in the attribute summary table to serve as an item to be configured of the target component. Therefore, the requirements on the user can be reduced, the user operation is reduced, and under the condition that the user cannot completely master various specific components, the relational data model for expressing the rich equipment process can be generated only by configuring some parameter values according to the determined target component and the to-be-configured item.

In an optional embodiment, the dynamic configuration operation further includes a connection configuration operation, and after determining the device type of the target device, the method further includes: in response to a connection configuration operation for the target device, determining a first component from all components of the target device and determining a second component from all components except the first component; establishing a directed or undirected connection relationship between the first component and the second component, and using the connection relationship between the first component and the second component as the component-level configuration information.

Through the implementation manner, the relational data model with the component-level connection relation can be generated.

In an alternative embodiment, the connection relationship between the first component and the second component includes at least one of a material orientation relationship, an electrical connection relationship, and a data transmission orientation relationship. Therefore, various association modes can be provided for each component, and the method is favorable for representing equipment processes with richer information.

In an optional implementation manner, the preset data further includes a material type table, the dynamic configuration operation includes a material configuration operation, and the obtaining, based on the preset data and the selected target device, component level configuration information in the dynamic configuration operation in response to the dynamic configuration operation on the target device includes: responding to material configuration operation of a target component of the target equipment, and obtaining material composition information in the material configuration operation based on the material type table to serve as component level configuration information of the target component; generating, based on the component-level configuration information, a relational data model, comprising: and generating a relational data model with component-level material trend characteristics based on the material composition information. Therefore, a relational data model with component-level material trend characteristics can be obtained, and equipment processes with richer attributes can be reflected.

In an optional embodiment, the material composition information includes a type of a target material processed by the target component and a material attribute of the target material, and the responding to a material configuration operation on a target component of the target device obtains the material composition information in the material configuration operation based on the material type table, and as component-level configuration information of the target component, includes: responding to material configuration operation of the target assembly, and determining at least one material from all materials provided by the material type table as the target material according to the material configuration operation; calling a preset third mapping relation between the material type table and the attribute summary table based on the material type of the target material, and screening out at least one material characteristic item which accords with the third mapping relation from all attribute items provided in the attribute summary table; and taking the material type of the target material and the material attribute which is input aiming at the material characteristic item in the material configuration operation as component-level configuration information of the target component. Therefore, material attributes can be configured, and safety performance of the process of the analysis equipment can be simulated based on the material attributes of the components.

In an alternative embodiment, the method further comprises: for a plurality of assemblies which have established connection relations, when receiving an updating operation for a third assembly in the plurality of assemblies, updating content or material updating content according to attributes in the updating operation, and updating attributes or updating materials for the third assembly and associated assemblies which establish connection relations with the third assembly according to a preset linkage updating rule. Therefore, when the attribute or material data of one component is changed, the attribute or material of other components related to the component can be automatically updated based on the connection relation among the components, so that intelligent updating is realized.

In an alternative embodiment, the method further comprises: and generating an equipment process simulation diagram according to the relationship data model, wherein the equipment process simulation diagram is used for showing the interconnection relationship among the equipment in the same equipment process. Therefore, the relational data model can be visually displayed.

In an optional embodiment, the device process simulation diagram includes a plurality of device groups, each device group in the plurality of device groups includes a plurality of devices or a plurality of sub-device groups, and the method further includes: responding to a first display operation of a part of equipment groups in the equipment flow simulation diagram, and displaying a plurality of pieces of equipment or a plurality of sub-equipment groups included in the part of equipment groups selected under the first display operation; and responding to a second display operation of any equipment in any equipment group, and displaying all components of the equipment selected under the second display operation. Therefore, the device flow can be displayed in a multi-level mode based on the device flow simulation diagram.

In a second aspect, an embodiment of the present application provides an apparatus for processing device data, where the apparatus includes:

the configuration module is used for responding to dynamic configuration operation of target equipment and obtaining component level configuration information in the dynamic configuration operation based on preset data and the selected target equipment, wherein the preset data comprises an equipment type table, an attribute summary table and a component type table;

and the processing module is used for generating a relation data model based on the component level configuration information, and the relation data model is used for reflecting the process parameters of each device in the device process and/or the component level connection relation among the devices.

The device can execute the equipment data processing method provided by the first aspect, and can represent rich engineering attributes of the equipment process based on the generated relational data model.

In a third aspect, an embodiment of the present application provides an electronic device, including: a memory and a processor;

the memory has stored thereon a computer program executable by the processor, which computer program, when executed by the processor, performs the method of the first aspect as described above.

In a fourth aspect, an embodiment of the present application provides a storage medium, where a computer program executable by a processor is stored, and when the computer program is executed by the processor, the method provided in the foregoing first aspect is performed.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

Fig. 1 is a flowchart of an apparatus data processing method according to an embodiment of the present application.

Fig. 2 is a diagram of a data association architecture for describing device process information in an example provided by an embodiment of the present application.

Fig. 3 is a schematic diagram of a configuration interface in an example provided by an embodiment of the present application.

Fig. 4 is a schematic diagram of a component configuration interface in an example provided by an embodiment of the present application.

Fig. 5 is a schematic diagram of a component configuration interface in another example provided by an embodiment of the present application.

Fig. 6 is a schematic diagram of an update relationship of a device in an example provided by the embodiment of the present application.

Fig. 7 is a schematic diagram of a material configuration interface in an example provided by an embodiment of the present application.

Fig. 8 is a device flow simulation diagram in an example provided by an embodiment of the present application.

Fig. 9 is a device flow simulation diagram in another example provided by an embodiment of the present application.

Fig. 10 is a functional block diagram of an apparatus data processing device according to an embodiment of the present application.

Fig. 11 is a block diagram of an electronic device according to an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

The inventor has found that the device management technology in the prior art is mainly managed by the following device datamation systems.

First, a device management system: the static information of the management equipment is recorded by recording information such as a nameplate, a source, a manager, the use time of the equipment and the like of the equipment. The interest of this method is not in the equipment itself, but in recording management information such as daily maintenance, change, stock disposition, etc. of the equipment, and engineering attributes of the equipment applied to actual engineering cannot be reflected, for example, detailed process data of the equipment and association between the equipment and the equipment cannot be reflected.

Second, the equipment overhaul information system: the method mainly records information related to equipment maintenance, for example, change information, replacement time, replacement times, a responsible person and the like of key parts of the equipment. The focus of this approach is to record maintenance information, and not to focus on the engineering attributes of the equipment application to the actual project.

Thirdly, equipment management is carried out through a production optimization system, and parameters related to equipment optimization are mainly recorded, wherein the parameters comprise the processing capacity of the equipment, the side line yield and the like. The focus of the method lies in the overall parameters of the equipment and the overall operation condition of the whole equipment system, and does not concern the various components of the equipment and the parameters in the equipment.

Fourth, the change of parameters such as flow, pressure and temperature of the equipment is monitored in real time, but this method focuses on the parameters, rather than the equipment itself, for example, although an alarm is given and whether the parameters are abnormal is checked according to the change condition of the parameters, the relationship between the equipment and the equipment cannot be reflected. The focus of this method is that parameters, not equipment, although some alarm operation, tracking or checking parameter change can be set according to the parameter change, it is difficult to better reflect the connection relationship between the equipment, the material trend and the properties of each component of the equipment.

In view of this, the inventor proposes the following embodiments to improve the device management by implementing the device management to the component level, and implementing the device process with rich engineering attributes by implementing the device component datamation, the device connection relationship datamation, and the material trend datamation, so as to implement the device management. The equipment process or relationship data model obtained based on the embodiment of the application can provide data reference for the safety performance simulation analysis of the whole equipment process, and is beneficial to simulating and investigating weak points in the equipment process in an actual engineering scene.

In order to achieve the purpose of the embodiment of the present application, a data system implemented based on a relational database technology and capable of being used for storing a device process is provided, where the data system may execute the device data processing method provided in the embodiment of the present application, and the system may be used for storing information related to a device process configured by apparatuses/devices in the field of process engineering.

When the data system is applied to execute the device data processing method provided by the embodiment of the application, the device-specific flow needing to be built or simulated can be converted into an abstract data structure. For convenience of describing the device process, the features in the device process may be summarized first. Key features in a device process may include: equipment, equipment type, components, connection relation, material type, attributes.

Some features of an apparatus flow in the embodiments of the present application will be described below.

Equipment: the hardware structure is various hardware structures which form equipment flow (flow for short), and the hardware structure comprises an instrument, a device for sending control information and the like.

The device type: the category of equipment includes pumps, heat exchangers, level sensors, etc.

Assembly of: the components of the equipment can comprise a body, a material inlet, a material outlet, an information inlet, an information outlet and the like. The information inlet can be used for receiving control instructions, and the information outlet can be used for outputting real-time data such as temperature, liquid level and the like. Typically, a plant comprises 1-2 bodies (e.g. shell-and-tube heat exchangers with tube-side, two bodies with shell-side), at least 1 material outlet/inlet and an indefinite number of information outlets/inlets.

Connection relation: in the embodiment of the present application, the connection relationship between the devices is embodied by the connection relationship between the components of each device, for example, the connection relationship may be: the material outlet of the storage tank is connected to the material inlet of the pump, the minimum return line outlet of the pump is connected to the material inlet of the pump, and the liquid level information outlet of the tower bottom is connected to the information inlet of the safety instrument. The connection relation can be a structural connection relation, and can also be a directional transmission relation of materials, electricity and signals.

Materials: the method is a processing object in the oil refining and chemical production processes, and in the embodiment of the application, the material is an object which is circulated among various devices and components of the various devices.

The material types are as follows: is a material category and is generally classified into gas, liquid, solid, etc.

The attributes are as follows: the characteristics of the components and the materials are that the attributes of the components can be the design pressure of the process pressure container body, the design temperature of the material outlet of the heat exchanger and the like, and the attributes of the materials can be the flash points, the upper and lower explosion limits and other material characteristics of the materials.

For all equipment, the general classification into equipment can include types of fluid transfer equipment, heating equipment, heat exchange equipment, mass transfer equipment, reaction equipment, storage equipment, and the like. The fluid delivery apparatus: including various pumps, compressors, blowers, and pipelines and valves matched with the pumps, the compressors, the blowers, and the valves. Heating equipment: the equipment used for heating the oil to a certain temperature to vaporize the oil or providing heat for the oil to react is called as heating equipment. The heating apparatus may be classified into a cylindrical furnace, a vertical furnace, an inclined-roof furnace, etc. according to its structure. The heat exchange equipment comprises: the equipment for transferring heat from high-temperature fluid to low-temperature fluid to heat, condense and cool oil products, and recovering heat and saving fuel is called heat exchange equipment. The heat exchange equipment is of various types, and comprises a heater, a heat exchanger, a condenser, a cooler, a reboiler and the like according to the use purpose; the heat exchange mode can be divided into direct mixing type, heat accumulation type and dividing wall type. Mass transfer equipment: for separating out a part of components in a substance in a mixed state by utilizing some difference in physical properties (e.g., boiling point, density, solubility, etc.) between media. The mass transfer device is often in the form of a thin and tall column, and is therefore also commonly referred to as a column device, for example, a rectification column, an absorption column, a desorption column, an extraction column, and the like. The tower equipment can be divided into a plate tower and a packed tower according to the structure. Reaction equipment: for carrying out chemical and physical reactions, where chemical reactions are dominant and determinative, physical processes are ancillary or concomitant. The reaction equipment has many application scenes in oil refineries, for example, when catalytic cracking, catalytic reforming, hydrocracking and hydrofinishing are carried out, different types of reactors/reaction devices are needed to be adopted as the reaction equipment in corresponding scenes. A storage device: equipment used to store various oil, petroleum gas and other liquid/gas materials is called storage equipment or tanks. It can be divided into a vertical storage tank, a horizontal storage tank, a spherical storage tank and the like according to the structural characteristics.

Among the various types of apparatuses, apparatuses mainly used for oil refining and chemical production may be referred to as process apparatuses such as a furnace, a reaction apparatus, a tower apparatus, a heat exchange apparatus, etc., and apparatuses that may be used not only for oil refining and chemical production but also for other purposes may be referred to as general-purpose apparatuses such as various pumps, compressors, fans, valves, etc. Any device in the foregoing description may become a target device in the embodiments of the present application.

The following describes a device data processing method provided in an embodiment of the present application.

Referring to fig. 1, fig. 1 is a schematic view illustrating an apparatus data processing method according to an embodiment of the present disclosure, where the method is applicable to an electronic apparatus. The method is a method for reflecting device process information.

As shown in FIG. 1, the method includes steps S11-S12.

S11: and responding to the dynamic configuration operation of the target equipment, and obtaining component level configuration information in the dynamic configuration operation based on preset data and the selected target equipment, wherein the preset data comprises an equipment type table, an attribute summary table and a component type table.

When an equipment process needs to be set up, a user can select one or more equipment instances, the selected equipment instances are used as target equipment, attribute configuration is carried out on the target equipment, and configuration contents can include component attributes, material attributes, connection relations and the like which need to be given to the target equipment. During the configuration process, the configurable item of the user for the target device can be determined by preset data. The electronic device may then take, as component-level configuration information of the target device, content configured by the user for the configurable items of the respective components of the target device in response to the dynamic configuration operation for the target device.

S12: and generating a relation data model based on the component-level configuration information, wherein the relation data model is used for reflecting the process parameters of each device in the device process and/or the component-level connection relation among the devices.

Since some attribute configurations have been performed on the selected target device through S11 and component-level configuration information is obtained, the component-level configuration information of the target device may be added to the blank model through S12, so that the blank model has the target device to which the attribute has been added, or the component-level configuration information of the target device may be added to the existing relational data model through S12, and a new relational data model is generated based on the existing relational data model and the component-level configuration information obtained through S11, so that the new relational data model may include not only each device in the original model but also the newly added target device. The generated relationship data model can embody which specific devices in the device flow, the attributes of the components of each device and the connection relationship among the components of each device.

In one example, a user may build an equipment process based on the data association architecture shown in fig. 2 provided in the embodiment of the present application, the user only needs to select some equipment from existing equipment examples to configure, and after configuration is completed, a relationship data model generated by an electronic device may embody multiple attribute information of various engineering equipment in the same equipment process, for example, all the engineering equipment (corresponding to an engineering equipment table) in the same equipment process, engineering components (for the engineering component table) possessed by each engineering equipment, component connection relationships of each engineering component (a component connection mapping table may be obtained by configuring connection relationships between components through S11), process attributes of each engineering component (a process attribute item of each component may be configured through S11 to obtain an engineering component-attribute mapping table), and material attributes of each engineering component (the material attributes of each component can be configured through S11 to obtain an engineering component-material mapping table).

In this embodiment, before S11 is executed, in order to describe an apparatus flow in detail, the general types of apparatuses such as a fluid conveying apparatus, a heating apparatus, a heat exchange apparatus, a mass transfer apparatus, a reaction apparatus, and a storage apparatus are further divided to obtain individual apparatus types such as a pump, a heat exchanger, and a liquid level sensor, and an apparatus type table, an assembly type table, an attribute summary table, and a material type table are pre-established for all the individual apparatuses, for all the assemblies, for all the attributes, and for all the materials in a material library. When the preset data is applied to set up the equipment process, the preset data is regarded as fixed data which is configured in advance.

The preset data, which is a common part in the device process information, may include a plurality of preset data tables. The component level configuration information in S11 is used as the proprietary information of each device process, and is based on data obtained by performing dynamic configuration operations when a user establishes a device process by the method according to the embodiment of the present application.

As an implementation manner, the preset data table includes a plurality of mutually independent general tables, which may include, for example, an equipment type table, a material type table, a component type table, and an attribute general table. Under the condition that all the tables in the preset data table are mutually independent, a user can define the association relation among equipment, components and attributes by himself when carrying out dynamic configuration operation based on the preset data table.

As another implementation manner, as shown in fig. 2, the preset data table may include a plurality of mutually independent general tables, and a mapping relationship may be established between the tables, so as to obtain, by combination, corresponding mapping tables (i.e., various maps) to carry combined information, so that sub-tables derived from the general tables may be provided, for example, a device-component mapping table (or referred to as a component sub-table), a device-attribute mapping table, a component-attribute mapping table, and a material-attribute mapping table. Any component in the device-component mapping table must have the device type to which it belongs, for example, a pump material outlet belongs to a pump class device.

If the content of the preset data needs to be newly created and modified, a user (for example, a research and development worker) can perform updating operations such as newly creating and modifying the preset data configured in the data system in advance by logging in a specified account, so as to update and expand the preset data. For example, some preset data may be updated based on the device type setting interface shown in fig. 3, so that the device type may be added/modified, and various attributes under the added/modified device type may be added, changed, saved, and the like. For example, a new device may be added to the device type table for the user to invoke. Therefore, the situations of fast update of product equipment and equipment change in a production field can be met, even if equipment products in an actual process are fast to update, customized configuration can be completed only by modifying preset data, and for a user needing to build an equipment flow, the user only needs to configure on the basis of the provided preset data and fill in parameters needing to be embodied in the currently-to-be-built equipment flow without paying attention to the content of the preset data.

In an application scenario, before executing S11, integrity of the preset data may be checked, for example, whether the preset data is complete may be checked according to the current device library and the material library, and necessary supplementation (such as a new device type, a new material, and the like) is performed, and when it is determined that the preset data is complete, S11 is executed to obtain component level configuration information applicable to the current target device, obtain a corresponding relationship data model, and build a device flow.

In order to reduce the difficulty of data maintenance and improve the database paradigm, a foreign key constraint relationship can be adopted to associate various data tables. For example, the mapping table shown in table 3 may be generated based on the device table shown in table 1 and the attribute table shown in table 2.

TABLE 1

Device ID	Device name
		925	Tower feed pump
2096	Tower bottom discharge pump

TABLE 2

Attribute ID	Attribute name	Attribute data type
			1102	Number of bits	String
2603	Design temperature	Float

TABLE 3

Device ID	Attribute ID	Attribute value
			925	1102	P-101
925	2603	120
			2096	1102	P-201
2096	2603	310

From the three tables, it can be seen that the pump with the device ID (device ID) 925 has the device number P-101, the design temperature of the pump is 120 degrees celsius, the pump with the device ID 2096 has the device number P-201, and the design temperature is 310 degrees celsius. The combination mode based on the principle can also be used for expressing other mapping relations among equipment, components, materials and attributes.

The step of S11 will be described in detail below.

In this embodiment, the dynamic configuration operation in S11 may include a component configuration operation, a connection configuration operation, and a material configuration operation.

As one implementation, to generate the relational data model with the process parameters of the equipment so that the component-level process attributes of the target equipment can be reflected in the generated relational data model, S11 may include the sub-steps of: S111-S113.

S111: and responding to the selected operation of the target equipment, acquiring the equipment identity of the target equipment, taking the equipment identity of the target equipment as a key value, and determining the equipment type of the target equipment based on the equipment type table.

Each device has its own device ID, and for convenience of description, the ID is abbreviated as ID. The device type table comprises a plurality of device IDs and device names corresponding to the device IDs, and the device types can be determined through ID values in the table. For example, a device with a device ID of "925" may represent a "column feed pump" and a device with a device ID of "2096" may represent a "column bottom discharge pump". When the target device is selected and the device ID of the target device is determined, the device type of the device can be obtained by matching among all devices provided by the device type table according to the device ID of the target device.

In the case where the device type of the target device is determined, S112 may be performed.

S112: and responding to the component configuration operation of the target equipment, determining at least one component from all components provided by the component type table as the target component of the target equipment based on the equipment type of the target equipment, and determining at least one process attribute item from the attribute summary table as an item to be configured of the target component according to the type of the target component.

As an implementation manner of S112, the target component and the item to be configured may be determined based on a mapping relationship between device types, components and attributes configured in the preset data in advance. The components that each type of equipment should have or can have and the attribute items that each component under each type of equipment should have can be reflected through the pre-configured mapping relation. The application execution step of this embodiment may comprise the sub-steps of: S1121-S1122.

S1121: calling a first mapping relation between a preset device type table and a component type table based on the device type of the target device, and screening at least one component meeting the first mapping relation from all components provided by the component type table to serve as a target component of the target device.

The device-component mapping table may be generated in advance based on the device type table and the component type table, and may be used as a component sub-table subordinate to the device type table, where each device in the device type table may correspond to one component sub-table. In step S1121, the electronic device may call a corresponding device-component mapping table according to the device type of the target device, so as to screen out the components meeting the first mapping relationship. Each component in the device-to-component mapping table may be a target component.

S1122: and calling a second mapping relation between a preset component type table and an attribute summary table based on the component type of the target component, and screening at least one process attribute item which accords with the second mapping relation from all attribute items provided in the attribute summary table to serve as an item to be configured of the target component.

In which a component-attribute mapping table may be generated in advance based on a component type table and an attribute general table as an attribute sub-table subordinate to the component type table. In step S1122, the corresponding component-attribute mapping table may be called according to the component type of the target component, so as to screen out the process attribute items meeting the second mapping relationship. Various attribute items in the component-attribute mapping table can be used as items to be configured of the target component.

Through the implementation manner of S1121-S1122, by configuring the mapping relationship among various tables of preset data in advance, the components that each type of device must or can have and the attributes that each type of device must or can have are configured in advance, and in the use stage, the target component of the current target device and the to-be-configured item of the target component can be determined only by calling the preconfigured mapping relationship. Therefore, the requirements on the user can be reduced, the user operation is reduced, and under the condition that the user cannot completely master various specific components, only parameter value configuration is needed according to the determined target component and the items to be configured.

As another implementation manner of S112, the target component and the item to be configured may be set for the current target device in a temporary configuration manner. That is, when receiving a component configuration operation for a target device, all components of the component type table may be exposed, a selected operation for a part of components in the component type table may be received, and the selected part of components may be used as target components of the target device for subsequent configuration. Similarly, when receiving a component configuration operation, all the attribute items provided by the attribute summary table may be presented, and when receiving a selection operation for a part of the attribute items in the attribute summary table, the selected part of the attribute items is taken as an item to be configured of the target component. This implementation can meet flexible configuration requirements.

In the case of determining the target component of the target device and the item to be configured of the target component, S113 may be performed: and taking the component name recorded for the target component in the component configuration operation and the process attribute parameter recorded for the item to be configured of the target component as the component-level configuration information of the target component.

In one example, the property entry or modification on the component can be performed on the selected target device through the component configuration interface shown in fig. 4, so as to set the device composition basic information of the target device.

As shown in fig. 4, the component configuration interface includes a default device ID and configurable columns such as "device component type", "device component code", "device component name", and the like. When the component of the single safety valve inlet is selected from the components provided by the equipment composition type, the component of the single safety valve inlet is used as the target component of the current target equipment. For the target component of the "individual safety valve inlet", information such as a component number and a component name may be entered in the "device composition code" and the "device composition name". When receiving attribute configuration operation for the target component, i.e. the "individual safety valve inlet", at least one fillable attribute item is displayed on the attribute setting interface, for example, the process attribute items, such as "operating pressure", "operating temperature", "design vacuum degree", "design (closing) pressure", "lowest tolerance temperature", "design temperature", and the like shown in fig. 4, can be used as the items to be configured of the target component, i.e. the "individual safety valve inlet", and the process attribute parameters entered for these items to be configured will be used as component-level configuration information of the target component.

Through the implementation mode of S111-S113, component-level attribute configuration can be performed on currently selected target equipment, and the component-level configuration information obtained based on the implementation mode of S111-S113 can record special engineering attributes for the target equipment and generate a relational data model with the process parameters of the equipment. The generated relationship data model may reflect the component-level process attributes of the target device, and for example, an operation pressure value, a minimum tolerance temperature value, and the like of a component, which is an inlet of an individual safety valve of the target device, may be reflected in a device process corresponding to the relationship data model.

In the embodiment of the present application, the dynamic configuration operation in S11 described above may further include a connection configuration operation, and after determining the device type of the target device, the method may further include sub-steps S114 to S115.

S114: in response to a connection configuration operation for the target device, a first component is determined from all components of the target device, and a second component is determined from all components except the first component.

The second component may be a component on a device other than the target device or may be a component of the target device itself. Therefore, the connection relation between the inlet and the outlet of the target component of the target equipment and other equipment can be set, and the connection relation of the internal components of the equipment can be configured aiming at some equipment with a feedback function.

S115: and establishing a connection relation between the first component and the second component, and taking the connection relation between the first component and the second component as component-level configuration information.

Wherein a directed or undirected connection relationship may be established between the first component and the second component.

In one example, the configuration of connections between components may be performed through a configuration interface as shown in FIG. 5. As shown in fig. 5, a component "individual safety valve inlet" may be selected from local components of the target device as a first component, one or more components may be selected from components of other devices (for example, a pump with a device number P-102) as a second component, the components to which the component "individual safety valve inlet" may be connected are shown in a "device external interface list", and when a "centrifugal pump inlet safety valve interface" is selected from components (a centrifugal pump outlet, a centrifugal pump discharge/condensation port, a centrifugal pump inlet safety valve interface, a centrifugal pump minimum return port, and a centrifugal pump information transmission port) provided in the "device external interface list" and added to the "connected device interface list" and a confirmation operation is performed, an oriented or undirected connection relationship is established between the component "individual safety valve inlet" and the component "centrifugal pump inlet safety valve interface", the component connection relationship between the two is used as the component level configuration information of the current target device. Based on such configuration, a relational data model with component-level connectivity relationships can be generated. When the relational data model is represented as a visualized simulation graph, the connection relationship between the component "individual safety valve inlet" of the target device and the component "centrifugal pump inlet safety valve interface" in the pump with the device number P-102 can be shown in the simulation graph.

Through the implementation manner of the S114-S115, the relationship data model with the component-level connection relationship can be generated, and when the relationship data model is visually displayed, the connection relationship of each device in the device process at the component level can be reflected, instead of only the macroscopic device connection relationship, which is beneficial to detailed management of devices with complex device processes and complex component associations.

Alternatively, intelligent linkage update can be realized for a plurality of components which have established connection relations. For a plurality of assemblies which have established connection relations, when receiving an updating operation for a third assembly in the plurality of assemblies, updating contents or material updating contents according to attributes in the updating operation, and updating attributes or updating materials for the third assembly and associated assemblies which establish connection relations with the third assembly according to a preset linkage updating rule.

The association component is a component of the plurality of components. The updating operation for the third component can be an attribute updating operation and can also be a material updating operation. The preset linkage updating rules can comprise attribute updating rules and material updating rules.

As an implementation manner, when an attribute updating operation for a third component in the multiple components is received, the attribute of the third component and the attribute of the associated component establishing a connection relationship with the third component may be updated according to a preset attribute updating rule and the attribute content in the attribute updating operation.

The preset attribute updating rule may include synchronous updating, non-updating, and updating according to a calculation expression. For example, for a valve without temperature difference, when the temperature value of the valve inlet is updated, the valve outlet connected with the valve inlet is automatically and synchronously updated, so that the temperature of the valve outlet is consistent with the temperature of the valve inlet. For a pressure reducing valve which will generate a pressure drop, when the temperature value of a valve inlet of the pressure reducing valve is updated, the temperature of the valve outlet connected with the valve inlet is not updated, but a manual update prompt can be sent. For a pump, the pressure data of the fluid at the outlet of the pump can be updated according to the pressure data of the fluid at the inlet of the pump, and the fluid pressures at the inlet and the outlet meet a fixed pressure difference. Based on the principle, the attribute updating can be carried out on the components connected with each other among different devices.

As an implementation manner, when a material update operation for a third component in the multiple components is received, the material update may be performed on the attribute of the third component and the associated component establishing the connection relationship with the third component according to a preset material update rule and material update content in the material update operation.

Wherein, the preset material updating rule may include synchronous updating. Illustratively, for the devices with established connection relations, when there is a directional connection relation between the components of each device, if the material inlet and outlet of one of the devices performs material updating operation, a third component is determined, and based on the direct or indirect connection relation between the components, the material inlet and outlet of each device are synchronously updated to ensure that the processing objects of the corresponding devices are the same material. It should be noted that the component performing the update is an association component that establishes a connection relationship with the third component.

In one example, as shown in fig. 6, several devices labeled as "reactor No. 3", "pump No. 6", "heat exchanger No. 1", "heat exchanger No. 2", "heat exchanger No. 3", and "rectifying column No. 4" establish a directional connection relationship as shown in fig. 6, and assuming that these devices only have one set of material inlet and outlet and one set of information inlet and outlet, when updating the temperature attribute, the temperature data of the part information inlet and outlet may be automatically filled so that the temperature of the information outlet of the reactor No. 3 is equal to the temperature of the information inlet of the pump No. 6, and the temperature of the information outlet of the pump No. 6 is equal to the temperature of the information outlet of the pump No. 6, and when updating the pressure attribute, the pressure data of the part information inlet and outlet may be automatically filled so that the pressure of the information outlet of the pump No. 6 is equal to the pressure of the information inlet of each heat exchanger (nos. 1 to 3) is equal to the pressure of the information outlet of the rectifying column No. 4, when the material is updated, part of the material composition at the material inlet and outlet can be automatically filled, so that the material at the material outlet of the No. 3 reactor is equal to the material at the material inlet of the No. 6 pump, and the material at the material outlet of the No. 6 pump is equal to the material at the material inlet of each heat exchanger (No. 1 to No. 3), and the material at the material outlet of each heat exchanger (No. 1 to No. 3) is equal to the material at the material inlet of the No. 4 rectifying tower.

The realization mode can quickly update the data of the components which are mutually associated, avoids the condition that other components still keep the original process attribute after the process attribute of one component is updated, and is favorable for providing reliable data reference for the safety performance analysis of the equipment process by the realization mode of dynamically and cooperatively updating the process attribute of each component.

Optionally, in this embodiment of the application, when performing the connection configuration operation, one or more connection relationships between the first component and the second component may be configured, and the connection relationship between the first component and the second component may be a directed connection relationship. The connection relationship between the first component and the second component may include at least one of a material strike relationship, an electrical connection relationship, and a data transmission strike relationship.

For some components needing to transmit materials, the material direction among the components can be configured, and for some components needing to transmit electric signals, the electric connection relation and/or the data transmission direction relation among the components can be configured. Therefore, various association modes can be provided for the components of each device, and the device process with richer information can be embodied.

In this embodiment, the dynamic configuration operation in S11 may further include a material configuration operation, and the S11 may further include a substep S116.

S116: and responding to the material configuration operation of the target component of the target equipment, and obtaining material composition information in the material configuration operation based on the material type table to serve as component-level configuration information of the target component.

Based on the material composition information obtained in S116, the above S12 may include: and generating a relational data model with component-level material trend characteristics based on the material composition information.

The material configuration operation can configure the mixing type and proportion of the materials and also configure the characteristics of the materials.

In one example, to determine the processing objects for a component, configuration may be performed with reference to the material property configuration interface shown in FIG. 7. As shown in fig. 7, for a target device with a device ID 15958, a component of the target device "individual safety valve inlet" is selected as a target component for which a single material or a mixed configuration of multiple materials can be performed. For example, the materials may be mixed based on a plurality of different standard materials selected by a user and a set mixing ratio, and the calculated material attributes after mixing are saved in a database, and the material composition information of the "individual safety valve inlet" of the target device is used as the component level configuration information. The generated relational data model can reflect the material information of the target component, and when the relational data model with the component-level material trend characteristics is visually displayed, what materials are circulated or processed by each component (outlet and inlet) of each device in the same device process can be displayed.

In some application scenarios, in order to perform safety analysis on an equipment process, considering that when a component of the equipment leaks, material properties such as toxicity and flammability of a material in the component will be regarded as important analysis indicators, and when performing industrial production, some material properties need to be paid attention to, therefore, S116 may include: S1161-S1163.

S1161: and responding to the material configuration operation of the target component, and determining at least one material from all materials provided by the material type table as a target material according to the material configuration operation.

The target material can be one material or a mixture of multiple materials.

S1162: and calling a third mapping relation between a preset material type table and an attribute summary table based on the material type of the target material, and screening at least one material characteristic item which accords with the third mapping relation from all attribute items provided in the attribute summary table.

For example, when the target material is a material formed by mixing 3 materials, the original material attribute items of the 3 materials can be all used as the material characteristic items of the target material, and a small number of material attribute items can be determined to be used as the material characteristic items of the target material according to the mixing characteristics of the 3 materials.

S1163: and taking the material type of the target material and the material attribute which is input aiming at the material characteristic item in the material configuration operation as component-level configuration information of the target component.

The material-attribute mapping table can be generated in advance based on the material type table and the attribute general table and serves as an attribute sub-table subordinate to the material type table. After the target material is determined, some material characteristic items can be screened from the material-attribute mapping table for attribute entry, so that the material characteristics of the target material are obtained. These material characteristics may include flash point, explosive limit, temperature, relative density, contraindications for contacts, etc.

In some application scenarios, the material properties of part of the materials can be calculated according to the components of the mixed materials, in this case, the material characteristic parameters of the target materials can be introduced after the target materials are determined, and some material properties need to be configured separately. For example, for the boiling point temperature of a material, the boiling point temperature may be default or estimated according to an expression, and the safe operating temperature of the material may be configured by a user.

It is understood that the above-mentioned S115-S116, S111-S113, and S114-S115 can be used in combination to generate a relational data model with rich engineering attributes, describing a device process with more complex feature information.

Optionally, based on the relationship data model generated at S12, the device data processing method may further include step S13.

S13: and generating an equipment process simulation diagram according to the relationship data model, wherein the equipment process simulation diagram is used for showing the interconnection relationship among the equipment in the same equipment process.

The device process simulation diagram can be understood as an expression form of the relational data model, and can be a two-dimensional diagram or a three-dimensional diagram.

In one example, based on the generated relational data model, a plant flow simulation diagram as shown in FIG. 8 can be obtained. The interconnection of three units in a unit sequence is shown in fig. 8, in which unit a2 with unit level number PSV-111 comprises 3 valves connected in series, the valve acting as the material stream inlet for the entire unit a2 being connected to unit a1 with unit level number P-102, and the valve acting as the material stream outlet for unit a2 being connected to another unit A3 with unit level number P-102. Material editing buttons and component editing buttons (such as small dots in FIG. 8) of each component can also be shown in the device flow simulation diagram. When the triggering operation of the material editing button is received, the materials which are circulated and processed in the currently selected component can be changed, or multiple mixed materials are remixed according to a new mixing proportion, or the material attributes of the materials in the component are reconfigured. When a triggering operation for the component editing button is received, the name, the process parameters and other component attributes of the currently selected component can be reconfigured.

In another example, the number of devices in the same device process is large, for example, up to thousands, in which case, the device process simulation diagram may be displayed in a multi-level display manner. The device process simulation diagram may include a plurality of device groups, and each device group of the plurality of device groups may include a plurality of devices or a plurality of sub-device groups. A plurality of devices having an interconnection relationship may be regarded as a device group module.

Optionally, the device data processing method may further include: s14 and S15.

S14: and responding to a first display operation of the partial equipment group in the equipment flow simulation diagram, and displaying a plurality of pieces of equipment or a plurality of sub-equipment groups included in the partial equipment group selected under the first display operation.

S15: and responding to the second display operation of any equipment in any equipment group, and displaying all components of the equipment selected under the second display operation.

Through S14-S15, device process information at different levels can be displayed under different conditions, readability of device processes can be enhanced by adopting a display mode of multi-level device groups, when a device group is taken as a minimum display unit, a connection relationship between the device groups can be displayed, when each device group is displayed in a detailed manner, a sub-device group or a device in the device group can be displayed, and for example, the device process simulation diagram shown in fig. 9 can be obtained.

Fig. 9 shows a device-level connection relationship of multiple devices in a device process, and a device-level material direction (represented by an arrow in fig. 9), where device numbers of the devices in fig. 9 are: d-111, D-101, D-103, P-101A/B, D-102, P-102, PSV-111, PSV-1112. Wherein D-111, D-101, D-103, and D-102 may be a subset of devices. For a device process simulation diagram of a device process including a plurality of devices, all components of a selected part of the devices under a second display operation may be displayed in response to the second display operation for the part of the devices in the device process simulation diagram. For example, for the device process simulation diagram shown in fig. 9, when three devices with device numbers P-102, PSV-111, and PSV-112 are selected, all components of the three devices and component-level connection relationships of the three devices may be displayed, and a user may refer to component information (including connection relationships, process parameters, material information, and the like) of each device in the same device process at any time.

Through the implementation mode, multi-level display of the equipment process can be achieved, not only can the interconnection relation of the equipment group level and the equipment level be displayed, but also the interconnection relation of each piece of equipment at the component level can be displayed, and it can be understood that more levels of interconnection relation can be generated based on the generated relation data model, and the complex equipment process is macroscopically displayed in a mode that the equipment is combined into a module. The multi-level display mode is beneficial to the macro and micro equipment management of the complex equipment flow.

In summary, the method and the data system provided by the embodiments of the present application may have the following advantages: compared with the traditional 3D modeling system only in appearance, the equipment or the data system for executing the method of the embodiment of the application can not only bear the category information of various kinds of equipment in the equipment flow list, but also store the information of engineering design parameters, material parameters, connection relations and the like of the equipment, and can provide a data basis for the applications of process calculation, safety analysis and the like. And the property setting of each device, the components of the device and the materials has customizability. And when the attribute of the future equipment process item is changed, the new equipment process information is convenient to modify and display. Because the data granularity and the equipment connection relation of the equipment are refined to the component level, the relation data model is generated based on the component level configuration information of the equipment, the trends of pipelines and materials of the equipment can be more effectively and clearly reflected based on the generated relation data model, a user can conveniently and fully analyze the data, and the problem that an equipment management scheme in a coarse-granularity management mode cannot be expressed in many process details is solved.

Based on the same inventive concept, please refer to fig. 10, an embodiment of the present application further provides an apparatus 200 for device data processing, which includes: a configuration module 201 and a processing module 202.

The configuration module 201 is configured to respond to a dynamic configuration operation on a target device, and obtain component level configuration information in the dynamic configuration operation based on preset data and the selected target device, where the preset data includes a device type table, an attribute summary table, and a component type table.

The processing module 202 is configured to generate a relationship data model based on the component-level configuration information, where the relationship data model is used to reflect process parameters of each piece of equipment in the equipment flow and/or a component-level connection relationship between each piece of equipment.

Optionally, the configuration module 201 may further be configured to: responding to the selected operation of the target equipment, acquiring an equipment identity of the target equipment, and determining the equipment type of the target equipment based on an equipment type table by taking the equipment identity of the target equipment as a key value; responding to component configuration operation of the target equipment, determining at least one component from all components provided by the component type table as the target component of the target equipment based on the equipment type of the target equipment, and determining at least one process attribute item from the attribute summary table as an item to be configured of the target component according to the type of the target component; and taking the component name recorded for the target component in the component configuration operation and the process attribute parameter recorded for the item to be configured of the target component as the component-level configuration information of the target component.

Optionally, the configuration module 201 may further be configured to: calling a first mapping relation between a preset device type table and a component type table based on the device type of the target device, and screening at least one component which accords with the first mapping relation from all components provided by the component type table to serve as a target component of the target device; and calling a second mapping relation between a preset component type table and an attribute summary table based on the component type of the target component, and screening at least one process attribute item which accords with the second mapping relation from all attribute items provided in the attribute summary table to serve as an item to be configured of the target component.

Optionally, the configuration module 201 may further be configured to: in response to a connection configuration operation for the target device, determining a first component from all components of the target device, and determining a second component from all components except the first component; and establishing a connection relation between the first component and the second component, and taking the connection relation between the first component and the second component as component-level configuration information.

Optionally, the device data processing apparatus 200 may further include an update module, the update module operable to: when receiving an attribute updating operation for a third component in the plurality of components, updating the attribute of the third component and the attribute of the associated component establishing a connection relation with the third component according to a preset attribute updating rule and attribute contents in the attribute updating operation.

Optionally, the configuration module 201 may further be configured to: in response to the material configuration operation on the target component of the target device, the material composition information in the material configuration operation is obtained based on the material type table and is used as the component-level configuration information of the target component, and the processing module 202 is further configured to generate a relational data model with component-level material trend characteristics based on the material composition information.

Optionally, the configuration module 201 may further be configured to: responding to material configuration operation of the target assembly, and determining at least one material from all materials provided by the material type table as a target material according to the material configuration operation; calling a third mapping relation between a preset material type table and an attribute summary table based on the material type of the target material, and screening out at least one material characteristic item which accords with the third mapping relation from all attribute items provided in the attribute summary table; and taking the material type of the target material and the material attribute which is input aiming at the material characteristic item in the material configuration operation as component-level configuration information of the target component.

Optionally, the device data processing apparatus 200 may further include a display module, and the processing module 202 may further be configured to generate a device flow simulation diagram according to the relationship data model, and the display module is configured to display the device flow simulation diagram, so as to show an interconnection relationship between devices in the same device flow.

Optionally, the display module may be further configured to: responding to a first display operation of a part of equipment groups in the equipment flow simulation diagram, and displaying a plurality of pieces of equipment or a plurality of sub-equipment groups included in the selected part of equipment groups under the first display operation; and responding to the second display operation of any equipment in any equipment group, and displaying all components of the equipment selected under the second display operation.

The device can execute the equipment data processing method, and can solve the problem that the equipment management scheme in the prior art cannot reflect the engineering attributes of each piece of equipment in an actual engineering scene.

For other details of the device data processing apparatus 200 provided in the embodiment of the present application, please refer to the foregoing description related to the device data processing method, which is not repeated herein.

Based on the same inventive concept, please refer to fig. 11, an embodiment of the present application further provides an electronic device 300. The electronic device 300 may be a personal computer, a tablet computer, a mobile phone, a server, an industrial personal computer, or other devices with arithmetic processing capabilities. The electronic device 300 includes: memory 301, processor 302, communication bus 303, display unit 304. The memory 301, the processor 302, the communication bus 303 and the display unit 304 are directly or indirectly connected to realize data interaction. The communication bus 303 is used to enable communication connections between the various internal structures of the electronic device 300.

The memory 301 is a storage medium, and may be a high-speed RAM memory or a non-volatile memory (non-volatile memory), such as at least one magnetic disk memory. The memory 301 stores therein a computer program, and the computer program stored in the memory 301 executes the aforementioned device data processing method when executed by the processor 302. The memory 301 may also be used to store preset data, component level configuration information, and data content of the relational data model.

The Processor 302 has an arithmetic Processing capability, and may be a general-purpose Processor such as a Central Processing Unit (CPU), a Network Processor (NP), a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA), or a special-purpose Processor built by other programmable logic devices or discrete hardware components. The processor 302 may implement or perform the methods, steps, and logic blocks disclosed in the embodiments of the present application. A general purpose processor may be a microprocessor or the processor 302 of the electronic device 300 may be any conventional processor.

The display unit 304 may be a liquid crystal display or a touch display, and is used for providing an interactive interface for a user, or displaying a simulation graph, parameters, and the like obtained for describing a device process.

The structure shown in fig. 11 is only an illustration, and there may be more components or other arrangements different from those shown in fig. 11 in specific applications.

Based on the same inventive concept, embodiments of the present application further provide a storage medium, where a computer program executable by a processor is stored on the storage medium, and the computer program, when executed by the processor, executes the foregoing device data processing method. The storage medium may include various media that may store program codes, such as a usb disk, a removable hard disk, a memory, and the like.

In the embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above-described embodiments are merely illustrative, and for example, a module may be divided into only one logical function, and another division may be implemented in practice. The functional modules in the embodiments of the present application may be integrated together to form an independent part, or each module may exist separately, or two or more modules may be integrated to form an independent part. The technical solutions of the present application may be embodied in the form of software products, or portions thereof that substantially contribute to the prior art.

In this document, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions.

The above embodiments are merely examples of the present application and are not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. A method of device data processing, the method comprising:

responding to dynamic configuration operation for a target device, wherein the dynamic configuration operation comprises component configuration operation and connection configuration operation; obtaining component level configuration information in the dynamic configuration operation based on preset data and the selected target equipment, wherein the preset data comprises an equipment type table, an attribute summary table and a component type table; responding to the selected operation of the target equipment, acquiring the equipment identity of the target equipment, and determining the equipment type of the target equipment based on the equipment type table by taking the equipment identity of the target equipment as a key value; in response to a connection configuration operation for the target device, determining a first component from all components of the target device and determining a second component from all components except the first component; establishing a directed or undirected connection relationship between the first component and the second component, and taking the connection relationship between the first component and the second component as the component-level configuration information; responding to the component configuration operation of the target equipment, determining at least one component from all components provided by the component type table as the target component of the target equipment based on the equipment type of the target equipment, and determining at least one process attribute item from the attribute summary table as an item to be configured of the target component according to the type of the target component; taking the component name entered for the target component in the component configuration operation and the process attribute parameter entered for the item to be configured of the target component as component-level configuration information of the target component;

and generating a relation data model based on the component-level configuration information, wherein the relation data model is used for reflecting the process parameters of each device in the device process and/or the component-level connection relation among the devices.

2. The method according to claim 1, wherein the determining, based on the device type of the target device, at least one component from all components provided by the component type table as a target component of the target device, and determining, according to the type of the target component, at least one process attribute item from the attribute summary table as an item to be configured of the target component comprises:

calling a preset first mapping relation between the equipment type table and the component type table based on the equipment type of the target equipment, and screening out at least one component which meets the first mapping relation from all components provided by the component type table to serve as a target component of the target equipment;

and calling a second mapping relation between the preset component type table and the attribute summary table based on the component type of the target component, and screening out at least one process attribute item which accords with the second mapping relation from all attribute items provided in the attribute summary table to serve as an item to be configured of the target component.

3. The method of claim 1, wherein the connection relationship between the first component and the second component comprises at least one of a material orientation relationship, an electrical connection relationship, and a data transmission orientation relationship.

4. The method according to claim 1, wherein the preset data further includes a material type table, the dynamic configuration operation includes a material configuration operation, and the obtaining component-level configuration information in the dynamic configuration operation based on preset data and the selected target device in response to the dynamic configuration operation for the target device includes:

responding to material configuration operation of a target component of the target equipment, and obtaining material composition information in the material configuration operation based on the material type table to serve as component level configuration information of the target component;

generating, based on the component-level configuration information, a relational data model, comprising:

and generating a relational data model with component-level material trend characteristics based on the material composition information.

5. The method according to claim 4, wherein the material composition information includes a type of a target material processed by the target component and a material property of the target material, and the responding to a material configuration operation for a target component of the target equipment obtains the material composition information in the material configuration operation based on the material type table as component-level configuration information of the target component includes:

responding to material configuration operation of the target assembly, and determining at least one material from all materials provided by the material type table as the target material according to the material configuration operation;

calling a preset third mapping relation between the material type table and the attribute summary table based on the material type of the target material, and screening out at least one material characteristic item which accords with the third mapping relation from all attribute items provided in the attribute summary table;

and taking the material type of the target material and the material attribute which is input aiming at the material characteristic item in the material configuration operation as component-level configuration information of the target component.

6. The method of claim 1, further comprising:

for a plurality of assemblies which have established connection relations, when receiving an updating operation for a third assembly in the plurality of assemblies, updating content or material updating content according to attributes in the updating operation, and updating attributes or updating materials for the third assembly and associated assemblies which establish connection relations with the third assembly according to a preset linkage updating rule.

7. The method according to any one of claims 1-6, further comprising:

and generating an equipment process simulation diagram according to the relationship data model, wherein the equipment process simulation diagram is used for showing the interconnection relationship among the equipment in the same equipment process.

8. The method of claim 7, wherein the device flow simulation graph includes a plurality of device groups, each device group of the plurality of device groups including a plurality of devices or a plurality of sub-device groups, the method further comprising:

responding to a first display operation of a part of equipment groups in the equipment flow simulation diagram, and displaying a plurality of pieces of equipment or a plurality of sub-equipment groups included in the part of equipment groups selected under the first display operation;

and responding to a second display operation of any equipment in any equipment group, and displaying all components of the equipment selected under the second display operation.

9. An apparatus for data processing of a device, the apparatus comprising:

the configuration module is used for responding to dynamic configuration operation of target equipment and obtaining component level configuration information in the dynamic configuration operation based on preset data and the selected target equipment, wherein the preset data comprises an equipment type table, an attribute summary table and a component type table; responding to the selected operation of the target equipment, acquiring the equipment identity of the target equipment, and determining the equipment type of the target equipment based on the equipment type table by taking the equipment identity of the target equipment as a key value; in response to a connection configuration operation for the target device, determining a first component from all components of the target device and determining a second component from all components except the first component; establishing a directed or undirected connection relationship between the first component and the second component, and taking the connection relationship between the first component and the second component as the component-level configuration information; responding to the component configuration operation of the target equipment, determining at least one component from all components provided by the component type table as the target component of the target equipment based on the equipment type of the target equipment, and determining at least one process attribute item from the attribute summary table as an item to be configured of the target component according to the type of the target component; taking the component name entered for the target component in the component configuration operation and the process attribute parameter entered for the item to be configured of the target component as component-level configuration information of the target component;

and the processing module is used for generating a relation data model based on the component level configuration information, and the relation data model is used for reflecting the process parameters of each device in the device process and/or the component level connection relation among the devices.

10. An electronic device, characterized in that the electronic device comprises:

a memory;

a processor;

the memory has stored thereon a computer program executable by the processor, the computer program, when executed by the processor, performing the method of any of claims 1-8.

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